Microbial Transformation and Degradation of Toxic Organic ChemicalsLily Y. Young, Carl E. Cerniglia This book examines the role of microbes, from theoretical, field, and applied perspectives, in the degradation of toxic organic chemicals. |
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Page 149
... remove exclusively meta chlorines and process P exclusively para chlorines . The other three dechlorination processes remove both meta and para chlorines , but with distinct specificities ( Tables 4.1 , 4.2 ) . Most of these processes ...
... remove exclusively meta chlorines and process P exclusively para chlorines . The other three dechlorination processes remove both meta and para chlorines , but with distinct specificities ( Tables 4.1 , 4.2 ) . Most of these processes ...
Page 167
... remove the para chlorine from 245 - CB , but not from 234 - CB . We concur with this interpretation and offer the following explanation of these results . As we discussed earlier , dechlorination processes M , N , H , H ' , and proba ...
... remove the para chlorine from 245 - CB , but not from 234 - CB . We concur with this interpretation and offer the following explanation of these results . As we discussed earlier , dechlorination processes M , N , H , H ' , and proba ...
Page 381
... removing low levels of glyphosate from high volume wastes . A summary of the results from pilot - scale testing of an immobilized bacteria reactor to remove glyphosate from a total plant effluent is shown in Figure 10.18 Percent Removal ...
... removing low levels of glyphosate from high volume wastes . A summary of the results from pilot - scale testing of an immobilized bacteria reactor to remove glyphosate from a total plant effluent is shown in Figure 10.18 Percent Removal ...
Contents
CHEMICAL CONTAMINATION OF | 27 |
CLEANUP OF PETROLEUM HYDROCARBON | 77 |
Bossert and Geoffrey C Compeau | 127 |
Copyright | |
13 other sections not shown
Common terms and phrases
acid activity added addition aerobic anaerobic Appl Environ Microbiol application Aroclor aromatic bacteria biodegradation biological bioremediation biphenyl carbon cells changes chemical chlorinated chlorophenols complete compounds concentration congeners contaminated cultures dechlorination dechlorination processes degradation dehalogenation demonstrated detected determine effect electron enrichment environmental enzymes et al example experiments factors field Figure gene Gibson glyphosate groups growth Hudson River hydrocarbons important increased indicated industrial initial involved isolated laboratory Lake levels limited mechanisms meta metabolism methods microbial microorganisms mineralization mixture naphthalene natural observed occur organic oxidation oxygen PAHs pathway pattern phenols populations potential present Pseudomonas reactions recently reductive relative removal reported responsible ring samples sediment selective showed shown sludge soil specific strain structure studies substrate suggested sulfate Table tion toluene toxic transformation treatment Ware waste